JPH06165014A - Zooming factor calculating method - Google Patents

Abstract

PURPOSE:To quantatively calculate the zooming factor of an enlarged image to one image. CONSTITUTION:The luminance signal of a reference image inputted from an input terminal 1 is stored in a frame memory 3, and the luminance signal of an enlarged image enlarging the reference image is stored in a frame memory 5. At a linear interpolating function part 6, the reference image stored in the frame memory 3 is linearly interpolated while setting a zooming factor and a zoom center prepared in advance and after the coefficient of correlation with the enlarged image stored in the frame memory 5 is calculated by a correlation coefficient calculation part 7, the correlation coefficient is stored through a zooming factor setting function part 8 into an optimum zooming factor storage part 9. The optimum zooming factor is calculated by repeating the operation of performing linear interpolation and calculating the correlation coefficient while setting the zooming factor or the zooming center at the zooming factor setting function part 8.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a zoom ratio calculating method for calculating the zoom ratio of an enlarged image.

[0002]

2. Description of the Related Art Digital transmission of television signals for television broadcasting has the characteristics that there is no deterioration in quality due to reproduction and relay and that a certain transmission quality can be obtained regardless of distance.
It has become possible to use the transmission line more effectively than analog transmission. When performing the above digital transmission, it is necessary to reduce the amount of image to be transmitted by a high efficiency encoding method such as redundancy removal based on the correlation of image signals in order to reduce the transmission cost. Therefore, the screen imaged by the television camera is also coded by the high efficiency coding method.

However, on the screen, the subject moves and the television camera moves and the entire screen moves in parallel. Even if the subject moves, there is almost no change in the shape of the screen, and the object simply moves in parallel. In many cases, it can be regarded as just.
Therefore, by detecting the direction and speed of the motion on the TV screen as described above by an appropriate method and performing an appropriate correction on the detected motion and then performing the encoding process, the code of the moving image part is further encoded. It is possible to improve the conversion efficiency.

In order to appropriately correct the movement of the screen imaged by the television camera, a method of quantitatively calculating the operation amount of the television camera using the imaged image is used. In the above method, for example, one screen is divided into blocks composed of a suitable number of pixels, and for each block,
There is a block matching method that detects the most similar block in the previous frame and calculates a motion vector based on the position of the detected block. By the block matching method, the amount of movement of the image in the parallel direction can be quantitatively expressed.

[0005]

By the way, the screen imaged by the television camera as described above includes a screen for enlarging and displaying an image by using the enlarging function of the television camera. Since there is no established method to calculate the enlargement ratio (that is, the zoom ratio) quantitatively, the size of the image may be different depending on the time when the images were taken. Even when the zoom ratio of the image is required, the zoom ratio cannot be quantitatively obtained.

In view of the above situation, it is an object of the present invention to provide a zoom ratio calculation method that quantitatively represents the zoom ratio of an image enlarged for one image.

[0007]

In the zoom ratio calculation method according to the present invention, a linearly interpolated image is set by setting an expected zoom ratio between one image and an enlarged image obtained by enlarging the image. Then, the correlation coefficient between the image subjected to the linear interpolation and the enlarged image is obtained, the zoom rate different from the zoom rate is set to perform the linear interpolation of the image, and the image subjected to the linear interpolation and the above Calculate the correlation coefficient with the magnified image, compare the correlation coefficient obtained first and the correlation coefficient obtained next and store a large value as the optimum zoom ratio, and for all values of the zoom ratio prepared in advance. , Sequentially from the setting of the above zoom ratio to the calculation of the correlation coefficient, a new correlation coefficient is calculated, and each time a new correlation coefficient is calculated, the newly calculated correlation coefficient and the correlation coefficient calculated in the past are calculated. Compare and calculate the newly obtained correlation coefficient in the past If it is larger than the correlation coefficient, to solve the problems described above by storing the correlation coefficient obtained newly as the optimal zoom ratio.

Further, when performing the linear interpolation, the value of the zoom center which is the center of the enlarged image is set in advance, and the optimum zoom ratio is obtained using the zoom center.

Further, a value estimated as the zoom center is set, linear interpolation of the image is performed, a correlation coefficient between the image subjected to the linear interpolation and the enlarged image is obtained, and it is estimated that the zoom center is close to the zoom center. In the process of repeatedly setting the values to be sequentially set and obtaining the correlation coefficient, the above-mentioned correlation coefficient becomes the maximum value, so that the precise zoom center value is gradually obtained. Is.

[0010]

In the present invention, the zoom ratio of an enlarged image obtained by enlarging the image captured by the television camera can be quantitatively expressed.

[0011]

EXAMPLE A preferred example of the present invention will be described below.
A description will be given with reference to the drawings. FIG. 1 is a configuration diagram showing a schematic device for carrying out a zoom ratio calculation method.
An image captured by a television camera or the like (hereinafter referred to as a reference image) and a luminance signal of an enlarged image obtained by enlarging the image are input from a luminance signal input terminal 1 on the device.

When the luminance signal of the reference image is input from the input terminal 1, the switch 2 is switched and the luminance signal of the reference image is stored in the frame memory 3. When the luminance signal of the enlarged image is input from the input terminal 1, the switch 4 is switched and the luminance signal of the enlarged image is stored in the frame memory 5.

In the linear interpolation function unit 6, the zoom ratio of the enlarged image with respect to the reference image is assumed and set, and the reference image is enlarged by linear interpolation. An example of the linear interpolation method is shown below.

As shown in the reference image in FIG. 2A and the enlarged image in FIG. 2B, the zoom center when the upper left of the reference image (a) is the origin is defined as (C _x , C _y ). To do. When the point on the reference image (a) is (x, y) and the point on the enlarged image (b) corresponding to the point (x, y) is (X, Y), the point (x, y) And the point (X, Y), the zoom ratio is k,

[0015]

[Equation 1]

It becomes as follows. Since the zoom rate k is assumed to be an arbitrary value, the point (x, y) does not always have an integer value on the pixel. Therefore, using linear interpolation, the point (x,
Create a pixel value for y). Here, the x value and the y value are respectively

[0017]

X = [x] + i (0 ≦ i <1) y = [y] + j (0 ≦ j <1) where [] is a Gauss symbol, [x] or [y] is a pixel It will be the upper value. Therefore, the positional relationship near the point (x, y) is as shown in FIG.

4 points A on a pixel near the point (x, y) A,
When the brightness values of B, C, and D are a, b, c, and d, the linear interpolation point P can be calculated using the distance to each point. Where each point A, B,
Distance to C and D AP, BP, CP, DP
Is

[0019]

[Equation 3] When the inverse ratio of the distance is used, the interpolation value p is

[0020]

[Equation 4] It can be obtained by the formula.

When j = 0, the interpolation value p to be obtained is the point A.
Exists on the line connecting point B and

[0022]

[Equation 5] It will be calculated by the formula.

When i = 0, the interpolation value p to be obtained is the point A
Exists on the line connecting point C and

[0024]

[Equation 6] It will be calculated by the formula.

When i = 0 and j = 0, the interpolation value p is the point A itself, and a is output as it is.

After the reference image is enlarged by the linear interpolation method as described above, the correlation coefficient calculation unit 7 calculates the correlation coefficient between the enlarged image of the reference image and the enlarged image. The calculation method of the correlation coefficient is shown below.

First, an image obtained by enlarging the reference image and pixel data sets X _i , Y _{i of the} enlarged image (i = 1, 2, ...
N)

[0028]

[Expression 7] X _i = {x ₁ , x ₂ , ..., X _N } Y _i = {x ₁ , x ₂ , ..., x _N } is expressed as an average value of each set. x _av , y
_av is

[0029]

[Equation 8] Can be calculated by On the other hand, the respective variances σ _x ² and σ _y ² are

[0030]

[Equation 9] And the covariance σ _xy of X _i and Y _i is

[0031]

[Equation 10] Therefore, the correlation coefficient γ can be obtained by the following equation.

[0032]

[Equation 11]

The correlation coefficient obtained by the above-mentioned procedure is stored in the optimum zoom ratio storage unit 9 as the optimum zoom ratio in the zoom ratio setting function unit 8.

After obtaining the first optimum zoom ratio, a zoom ratio different from the above-mentioned set zoom ratio is set, the linear interpolation function unit 6 performs linear interpolation again, and the correlation coefficient calculation unit 7 performs linear interpolation. The correlation coefficient between the split image and the enlarged image is calculated, and if the correlation coefficient calculated by the zoom ratio setting function unit 8 is larger than the value stored in the optimum zoom ratio storage unit 9, a new optimum The optimum zoom ratio storage unit 9 stores the zoom ratio. With respect to all the zoom ratios prepared in advance, the optimum zoom ratio is obtained by sequentially performing the operations from the setting of the zoom ratios to the comparison of the correlation coefficients as described above, and finally, the zoom values stored in the optimum zoom ratio storage unit 9 are stored. The rate is the final optimum zoom rate.

FIG. 4 is a flow chart showing the procedure for obtaining the optimum zoom ratio according to the present invention. As shown in step S1, the zoom ratio setting function unit 8 in FIG. 1 sets the value of the zoom ratio prepared in advance, and in step S2 the zoom which is the center of enlargement prepared and estimated in advance is prepared. Set the center value. Since the zoom center is optically determined, it is not always on the scanning line of the image. Therefore, it is necessary to set the estimated value of the zoom center to a precise value equal to or less than the pixel. If the zoom center value is known, that value is set.

Next, as shown in step S3, the linear interpolation function unit 6 performs linear interpolation on the reference image,
As shown in step S4, the correlation coefficient calculator 7 calculates the correlation coefficient between the image linearly interpolated in step S3 and the enlarged image for which the zoom ratio is to be obtained.

Thereafter, in the zoom ratio setting function section 8,
As shown in step S5, the calculated correlation coefficient is compared with the correlation coefficient already obtained and stored in the optimum zoom ratio storage unit 9, and if the calculated correlation coefficient is larger, After proceeding to step S6 and storing the calculated correlation coefficient in the optimum zoom ratio storage unit 9, step S7
Proceed to. If the value stored in the optimum zoom ratio storage unit 9 is larger than the calculated correlation coefficient, the stored optimum zoom ratio remains unchanged and the process proceeds to step S7.

Next, it is determined whether or not all the estimated zoom center values have been set. If all the zoom center values estimated and prepared in advance have been set, the process proceeds to step S8, but if not all set, the process returns to step S2 to set a zoom center value different from the previously set value. The operation for obtaining the correlation coefficient is continued until all the estimated zoom center values are set.

In step S8, it is determined whether or not all the zoom ratios have been set. When all the zoom ratios prepared in advance are set, the operation for calculating the optimum zoom ratio is completed. The value stored in the optimum zoom ratio storage unit 9 at this time is the final optimum zoom ratio. In step S8, if all the zoom ratios have not been set, the process returns to step S1 and the zoom ratio different from the previously set value is set to obtain the correlation coefficient. Continue until done.

In the present invention, when it is desired to take out a magnified image of a specified magnification with respect to one image, the zoom ratio between the images can be quantitatively obtained to facilitate the taking out of the zoomed image. It can be applied to various image editing devices.

[0041]

As is apparent from the above description, by using the zoom ratio calculation method according to the present invention, it is possible to quantify the zoom ratio of an enlarged image with respect to one image. Also, if you want to extract an image with the specified magnification for one image, the zoom ratio between the images can be obtained quantitatively, so it is easy to extract the enlarged image, and the zoom ratio can be displayed quantitatively. Therefore, it is easy to take out an image with the same zoom ratio.

Therefore, when the present invention is applied to an image editing apparatus or the like, it is possible to improve the editing accuracy of an enlarged image and the efficiency of editing time.

[Brief description of drawings]

FIG. 1 is a schematic diagram of an apparatus for implementing a zoom ratio calculation method according to the present invention.

FIG. 2 is a diagram schematically showing a reference image and an enlarged image according to the present invention.

FIG. 3 is a diagram showing a positional relationship of points in linear interpolation according to the present invention.

FIG. 4 is a flowchart showing a procedure for calculating an optimum zoom ratio according to the present invention.

[Explanation of symbols]

 1 ... Luminance signal input terminal 2,4 ... Switch 3,5 ... Frame memory 6 ... Linear interpolation function unit 7 ... --- Correlation coefficient calculator 8 --- Zoom ratio setting function 9 --- Optimal zoom ratio storage

Claims (3)

[Claims] 1. A linear interpolation of the image is performed by setting a zoom ratio assumed between one image and an enlarged image obtained by enlarging the image, and the image obtained by the linear interpolation and the enlarged image are combined. The correlation coefficient is calculated, a zoom ratio different from the zoom ratio is set, linear interpolation is performed on the image, the correlation coefficient between the image on which the linear interpolation is performed and the enlarged image is calculated, and the first calculated phase is calculated. A large value is stored as an optimum zoom ratio by comparing the number of relations and the correlation coefficient obtained next, and for all values of the zoom ratio prepared in advance, from the setting of the zoom ratio to the calculation of the correlation coefficient. A new correlation coefficient is obtained by performing an operation, and each time a new correlation coefficient is obtained, the newly obtained correlation coefficient is compared with the previously obtained correlation coefficient, and the newly obtained correlation coefficient is obtained in the past. If the value is larger than the correlation coefficient,
A zoom ratio calculation method, characterized in that a newly obtained correlation coefficient is stored as an optimum zoom ratio. 2. When performing the linear interpolation, a value of a zoom center, which is the center of the enlarged image, is set in advance, and the optimum zoom ratio is obtained using the zoom center. Zoom rate calculation method. 3. A value estimated as the zoom center is set, linear interpolation is performed on the image, a correlation coefficient between the image subjected to the linear interpolation and the enlarged image is obtained, and it is estimated that the zoom center is close to the zoom center. In the process of repeatedly setting the values to be obtained and obtaining the correlation coefficient repeatedly, the above-mentioned correlation coefficient becomes the maximum value, so that the precise zoom center value is gradually set. The zoom ratio calculation method according to claim 1 or 2.